DE202011051147U1 - Sprayer with rotating function - Google Patents

Abstract

Sprayer with rotating function,
characterized in that it consists of the following:
A conduit for the liquid, wherein at one end of the conduit for the liquid, a filling opening is formed, and at the other end of the conduit for the liquid, a nozzle opening is formed, and further a plurality of passages are formed on the wall of the conduit for the liquid .
- And further comprising a mechanism for the rotary drive, which is connected to the line for the liquid, and wherein the mechanism for the rotary drive an upper plate for the liquid, which is pressed forward, so that the liquid of the passage in the direction of the exit is directed, owns, and
In addition, the construction consists of a flow opening, and this is formed on a part of the upper plate for the liquid, and the upper plate for the liquid is connected by the liquid of the diversion space and receives at ...

Description

Area of construction

The design is the design of a sprayer. In particular, it is a rotating sprayer that drives a rotary actuator mechanism.

Description of previous designs

Various spray guns are widely used in cleaning surfaces to remove dust, dirt, spiky water, splashes of paint and more. This type of spray gun uses a high pressure gas that is sprayed out to clean up dust and dirt. Or a mixture containing water or other high pressure gases containing spray liquid to spray water or to spray a surface is used.

In order to obtain a uniform spray result, the spray line of the spray gun is made with a curved shape. And on the spray line of the spray gun, a rotating mechanism is attached. The spray line is driven by the rotating mechanism and rotates. Further, the high-pressure liquid and the liquid mixed with the spraying agent are uniformly sprayed outward in accordance with the rotation of the spraying line. As an example, this can be used for the rotary mechanism, an electric fan, which has several fan blades. The liquid under high pressure is introduced into the spray gun and then pulled forward by the fan blades and the rotating mechanism rotates. On the other hand, the rotation mechanism may be a motor. In this case, an external electrical force is used, which drives the rotary mechanism. And that drives the spray line, which then turns.

However, the shape of the fan blades is complicated, so that the strength of the construction is not optimal. The production and the reduction of the volume are so difficult and it is easy to waste and deformations. The engine also requires an external electrical force. The manufacturing costs and the cost of electrical energy are comparatively high.

Content of the construction

The technical problems of the construction to be solved

Examining the above description, it can be noted that in commonly known spray guns, a fan or a motor is used to drive the rotation of the spray gun's spray line. The manufacturing costs and the cost of electrical energy are comparatively high.

Therefore, the main objective of the design is to provide a rotary sprayer whose construction is solid, which is easy to manufacture, which allows a stable rotary motion and which does not require an external electric drive.

Methods of the solution of technical problems of construction

In order to solve the known technical problems, a spraying device with rotary function is presented for the technical method, which consists of the following components: From a line for the liquid, wherein at one end of the line for the liquid, a filling opening is formed, and at the other end the line for the liquid, a nozzle opening is formed, and further on the wall of the conduit for the liquid a plurality of passages are formed. Furthermore, the construction consists of a rotary drive mechanism connected to the fluid conduit, and a rotary drive mechanism has a top plate for the fluid which is pushed forward so that the fluid of the passage is directed toward the outlet becomes. In addition, the construction consists of a flow opening. This is formed on a part of the upper plate for the liquid. The upper plate for the liquid is connected by the liquid of the diversion space and receives at the passage of the liquid discharged the corresponding force. Furthermore, the construction consists of a conduit, wherein at one end a container of the filling opening is attached, which is connected to the mechanism for the storage of the liquid. And at the other end the line for the liquid is inserted and this extends to the nozzle opening.

In a first embodiment, the upper plate for the liquid of the mechanism for the rotary drive is gradually formed in the direction of the open line.

In the first embodiment, the mechanism for the rotary drive has a plurality of solid ribs extending from the line for the liquid drop. In the first embodiment, the mechanism for the rotary drive is composed of a front fixed layer, a rear fixed layer, and a flow channel layer interposed between the front fixed layer and the rear fixed layer. In addition, the front solid layer and the rear solid layer are made of a solid material, and the layer for the flow channel is made of a moldable material.

In the first embodiment, a discharge part is attached in the liquid line. The liquid flowing into the liquid line is divided into two parts. Part of the liquid flows to the nozzle opening of the liquid line. The other part of the liquid flows to the passage of the liquid line.

In the first embodiment, a flow rate adjustment mechanism, which consists of a wall for water separation and a shaft for sealing, is mounted in the conduit. On the wall for the water separation a limiting opening is attached. At one end of the shaft for the sealing a part for the gradual reduction is attached. The part for gradual reduction of the sealing stem is displaced and inserted in the limiting opening of the wall for water separation.

In the first embodiment, the rotational speed adjustment mechanism consists of a first adjustment mechanism and a second adjustment mechanism. And the first mechanism for the adjustment is connected to the flow opening of the mechanism for the rotary drive. Furthermore, a plurality of first openings are formed on the output surface. At the second mechanism for adjustment, an entrance surface is formed. The input surface of the second mechanism for adjustment is rotatably connected to the output surface of the first mechanism for adjustment. Furthermore, a plurality of second openings are formed on the entrance surface corresponding to the first openings.

Effectiveness of construction compared to previous techniques

The related engineering methods of construction do not require the use of an electric drive to cause the liquid line to rotate. With regard to the mechanism for the rotary drive, the upper plate for the liquid, the flow opening and the diversion space, these are arranged in the inner part of the mechanism for the rotary drive. The construction of the mechanism for the rotary drive is fixed in terms of manufacturing and can also be downsized. Furthermore, this type of mechanism for the rotary drive when turning can be kept completely stable. The rotation speed is uniform and the changes are minimal. This is advantageous for a uniform spraying of the liquid. The embodiments of the construction used are explained below by explanations of the embodiments and by illustrations.

Description of the construction

See below 1 . 2 and 3 , It is 1 a three-dimensional view of the first embodiment of the sprayer with rotary function. 2 is a representation of a section of 1 , And 3 is an enlarged view of a part of 2 , According to a first embodiment, there is a spray device with a rotating function 100 off device 1 , At one end of the device 1 becomes control handle 11 appropriate. At the bottom is on the device 1 a mechanism for the storage of the liquid 12 appropriate.

In the device 1 becomes conduit for the liquid 2 appropriate. The pipe for the liquid 2 penetrates a storage 20 and will with the device 1 connected. Furthermore, an axial rotation inside the sprayer with rotary function 100 respectively. The one end of the pipe for the liquid 2 extends into the control handle 11 , Furthermore, at one end of the line for the liquid 2 a filling opening 21 attached, so that the liquid F1 is introduced by itself. The other end of the pipe for the liquid 2 extends to one side of the device 1 , Furthermore, a nozzle opening 22 appropriate. The liquid F1, which enters the filling opening 21 is introduced leaves the nozzle opening by itself 22 , Furthermore, in the device 1 a mechanism for the rotary drive 3 used.

The mechanism for the rotary drive 3 is with the line for the liquid 2 connected to the rotation of the pipe for the liquid 2 to provide, so that a rotating spraying is enabled.

Furthermore, in the device 1 a line 4 appropriate. At one end of the pipe 4 becomes a container of the filling opening 41 attached and he is connected to the mechanism for storing the liquid 12 , At the other end of the line 4 becomes a container of the exit port 42 appropriate. The administration 4 is through the pipe for the liquid 2 inserted and extends to the nozzle opening 22 the line for the liquid 2 , If the liquid F1 by itself from the nozzle opening 22 the line for the liquid 2 sprayed out, so at the opening of the line a masking effect is achieved. The liquid F2, which is in the mechanism for storage of the liquid 12 is located over the line 4 sprayed outwards.

See below 4 and 5 , It is 4 a three-dimensional representation of the mechanism for the rotary drive and 5 is a representation of a section of the mechanism for the rotary drive. The mechanism for the rotary drive 3 consists in this embodiment of a front solid layer 3a and a rear solid layer 3b and from a layer for the flow channel 3c placed between the front solid layer 3a and the rear solid layer 3b is attached. The construction of the front solid layer 3a and the rear solid layer 3b is simply using a solid material for manufacturing such as metal or acrylic fiber. The construction of the layer for the flow channel 3c is more complicated. For this, malleable materials such as plastic or rubber are used. By this method, the production of the mechanism for the rotary drive 3 simply done. Nevertheless, the construction is not limited thereby. The layer for the flow channel 3c can also be made of a hard material. The mechanism for the rotary drive 3 is with the line for the liquid 2 connected. On the wall of the pipe for the liquid 2 become multiple passages 23 formed, wherein the mechanism for the rotary drive 3 is connected. Furthermore, in the line for the liquid 2 a derivation part 24 appropriate. The derivation part 24 is a tube in this embodiment. The derivation part 24 is through the pipe for the liquid 2 plugged. The pipe for the liquid 2 is then divided into two areas. Therefore, the liquid F1 becomes when passing through the discharge part 24 divided into two parts. At this time, part of the liquid F1 becomes the region on the inside of the discharge part 24 in the direction of the nozzle opening 22 the line for the liquid 2 directed. The other part of the liquid F1 is through the area of the outside of the discharge part 24 in the direction of the passage 23 the line for the liquid 2 directed. This part of the fluid F1 will pass through the passage 23 in the mechanism for the rotary drive 3 directed.

On the mechanism for the rotary drive 3 becomes an upper plate for the liquid 31 appropriate. At the top plate for the liquid 31 becomes the liquid of the passage 23 issued in the direction of the inclination. And at the end part of the upper plate for the liquid 23 becomes a flow opening 32 educated. The liquid F1, that of the passage 23 in the mechanism for the rotary drive 3 has passed is flowing along the diversion space 33 and exerts a force on the upper plate for the liquid. Thereafter, a forwarding of the flow opening takes place 32 until the mechanism for the rotary drive. During this process, the upper plate for the liquid receives the force which has started from the liquid F1, which flows out of the passage 23 was issued. Furthermore, mechanism for the rotary drive 3 put in a rotary motion. Then get the line for the liquid 2 the movement of the mechanism for the rotary drive 3 and it is executed a same rotational movement.

The direction of rotation of the mechanism for the rotary actuator 3 and the direction of inclination of the upper plate for the liquid 31 equal to. In this embodiment, the upper plate extends for the liquid 31 like on 5 to see gradually towards the open wire. The direction of rotation of the mechanism for the rotary actuator 3 corresponds to the clockwise direction. It should be noted that although the number of upper plates for the liquid is four in this embodiment. However, this should not be so limited. The number of upper plates for the liquid 31 should be one here. In this situation, the flow opening 32 between the front and the rear end of the upper plate for the liquid 31 educated. Furthermore, on the mechanism for the rotary drive 3 several solid ribs 34a / 34b attached, which differs from the line for the liquid 2 drop. This is the conduit for the liquid 2 in the center of rotation of the mechanism for the rotary drive 3 attached. This will reduce the inaccuracy when turning.

By showing the construction, it is possible that no electric drive is used, which serves for the rotation of the conduit for the liquid 2 to care. Through the top plate for the liquid 31 , de flow opening 32 and the diversion room 33 becomes the inner part of the mechanism for the rotary drive 3 educated. The construction of the mechanism for the rotary drive 3 is certain. And it is also easy to achieve a reduction. Furthermore, the construction of the mechanism for the rotary drive 3 when turning completely stable, and it is the rotation speed evenly and there is no change.

See below 6 , This is an illustration of a section of the mechanism for adjusting the flow rate. In order to control the amount of liquid F2 introduced which has been discharged from the pipe, in this embodiment, in the pipe 4 a mechanism for adjusting the flow rate 5 used. The mechanism for adjusting the flow rate 5 consists of a wall for water separation 51 , a shaft for sealing 52 and a mechanism for adjustment 53 , On the wall for the water separation 51 becomes a limiting opening 511 educated. The liquid F2 of the pipe flows 4 through into the limiting opening 511 , At one end of the shaft for the seal 52 becomes a part of the gradual reduction 521 appropriate. The part for gradual reduction 521 of the shaft for the seal 52 gets into the limiting opening 511 the wall for the water separation 51 emotional. At the other end of the shaft for the sealing 52 extends outwards to the device 1 , Furthermore, a connection with the mechanism for the adjustment takes place 53 (please refer 2 ). The mechanism for the adjustment 53 now represents the part for the gradual reduction 521 of the shaft for the seal 52 one being an insertion in the limiting opening 511 the wall for the water separation 51 he follows. This changes the size of the gap between the limiting aperture 511 and the part for the gradual reduction 521 , And so the amount of liquid F2 of the pipe can 4 be set.

See below 7 and 8th , 7 is a three-dimensional representation of the mechanism for adjusting the rotational speed and 8th is another three-dimensional representation of the mechanism for adjusting the rotational speed. To the rotational speed of the mechanism for the rotary drive 3 and the line for the liquid 2 adjust the sprayer with rotary function 100 with a mechanism for adjusting the rotational speed 6 Mistake. The mechanism for adjusting the rotational speed 6 consists of a first mechanism for the adjustment 61 and a second mechanism for adjustment 62 , The first mechanism for the adjustment 61 is with the flow opening 32 the mechanism for the rotary drive 3 connected. Furthermore, at the first mechanism for the adjustment 61 an exit area 611 educated. On the exit area 611 be several first openings 612 educated. Therefore, the liquid F1, which is on the mechanism for the rotary drive 3 flowed out into the mechanism for the setting 61 initiated. Then it flows out of the first opening 612 out. At the second mechanism for the adjustment 62 becomes an entrance area 621 educated. On the entrance area 621 be several second openings 622 formed the first openings 612 correspond. The entrance area 621 of the second mechanism for the adjustment 62 is rotatable on the output surface 611 the first mechanism for the adjustment 61 connected. By this construction, there is a corresponding rotational displacement between the first mechanism for adjustment 61 and the second mechanism for the adjustment 62 , This will increase the size of the gap between the first opening 612 and the second opening 622 changed. In this case, the flow amount of the liquid F1, which is the mechanism for the rotary drive 3 flowed out is set. Furthermore, this sets the flow rate, the rotational speed of the mechanism for the rotary drive 3 firmly.

From the embodiment shown above, it can be seen that the construction is a rotary sprayer. Thus, the described construction meets the requirements for a patent. The above description relates to the preferred embodiment of the construction. All sorts of changes to this design that can be made by experts in the technical field based on the above explanations are all within the scope of the patent.

List of Figures

1 is a three-dimensional view of the first embodiment of the sprayer with rotary function.

2 is a representation of a section of 1 ,

3 is an enlarged view of a part of 2 ,

4 is a three-dimensional representation of the mechanism for the rotary drive.

5 is a representation of a section of the mechanism for the rotary drive.

6 is a representation of a section of the mechanism for adjusting the flow rate.

7 is a three-dimensional representation of the mechanism for setting the rotational speed.

8th is another three-dimensional representation of the mechanism for adjusting the rotational speed.

LIST OF REFERENCE NUMBERS

100

Sprayer with rotating function

1

device

11

control handle

12

Mechanism for the storage of the liquid

2

Line for the liquid

20

storage

21

fill opening

22

nozzle opening

23

passage

24

sink section

3

Mechanism for the rotary drive

3a

Front solid layer

3b

Rear solid layer

3c

Layer for the flow channel

31

Upper plate for the liquid, pressed forward

32

flow port

33

Diversion room

34a

Solid rib

34b

Solid rib

4

management

41

Container of the filling opening

42

Container of exit port

5

Mechanism for adjusting the flow rate

51

Wall for water separation

511

Limiting opening

52

Shaft for the seal

521

Part for the gradual reduction

53

Mechanism for the adjustment

6

Mechanism for setting the rotational speed

61

First mechanism for the adjustment

611

output surface

612

First opening

62

Second mechanism for the adjustment

621

input surface

622

Second opening

F1

liquid

F2

liquid

Claims (8)

A rotary sprayer characterized in that it consists of the following: - a conduit for the liquid, a filling opening being formed at one end of the conduit for the liquid, and a nozzle opening being formed at the other end of the conduit for the liquid, and further, a plurality of passages are formed on the wall of the liquid conduit, and further comprising a rotary drive mechanism connected to the liquid conduit, and wherein the rotary drive mechanism comprises a liquid upper plate is pushed forward so that the liquid of the passage is directed toward the exit has, and - moreover, the construction consists of a flow opening, and this is formed on a part of the upper plate for the liquid, and the upper plate for the Liquid is connected and obtained by the fluid of the diversion space at the passage of the dispensed liquid, the corresponding force, and - further, the construction consists of a conduit, at one end of which a container of the filling opening is attached, which is connected to the mechanism for storing the liquid, and at the other end the line for the liquid is inserted and this extends to the nozzle opening, and wherein a part of the liquid which has been introduced from the filling opening into the line for the liquid flows through the passage and then into the mechanism for the rotary drive, and the the liquid upper plate receives the force of the liquid, and further the rotary drive mechanism is rotated, and further the liquid line is rotated to allow rotary spraying. Sprayer according to claim 1, characterized in that the upper plate for the liquid of the mechanism for the rotary drive in the direction of the open line is gradually formed. Sprayer according to claim 1 or 2, characterized in that the mechanism for the rotary drive has a plurality of solid ribs, which are deposited from the line for the liquid. Sprayer according to one of the preceding claims, characterized in that the mechanism for the rotary drive consists of a front solid layer, a rear solid layer and a layer for the flow channel, which is arranged between the front solid layer and the rear solid layer. A sprayer according to claim 4, characterized in that the front solid layer and the rear solid layer are made of a solid material, and the layer for the flow channel is made of a moldable material. Sprayer according to one of the preceding claims, characterized in that in the conduit for the liquid, a discharge part is attached, and the liquid which flows into the line for the liquid is divided into two parts, and a part of the liquid to the nozzle opening of the conduit for the liquid flows, and the other part of the liquid to the passage of the liquid line flows. Sprayer according to one of the preceding claims, characterized in that in the conduit a flow rate adjustment mechanism is provided which consists of a wall for water separation and a shaft for the sealing, and on the wall for water separation, a limiting opening attached and, at one end of the sealing stem, a gradual reduction part is attached, and the gradual reduction portion of the sealing stem is displaced and inserted into the limiting opening of the water separation wall. Sprayer according to one of the preceding claims, characterized in that the rotation speed adjustment mechanism consists of a first adjustment mechanism and a second adjustment mechanism, and the first adjustment mechanism is connected to the flow opening of the rotary drive mechanism and further, a plurality of first openings are formed on the output surface, and an input surface is formed on the second adjustment mechanism, and the input surface of the second adjustment mechanism is rotatably connected to the output surface of the first adjustment mechanism, and further on the entrance surface a plurality of second openings are formed corresponding to the first openings.

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